Structural facade having punctually suspended panes and window or wall frame system for said structural facade

ABSTRACT

A window or door frame for a structural facade, of the type having punctually suspended panes, comprises at least a first pane capable of moving, whereto a gasket is operatively associated, able to pass from a respective operative condition to a respective inoperative condition, and vice versa, as well as an actuating unit, able to be selectively operated to cause passage of said gasket between the respective operative and inoperative conditions.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the field of continuous structural facades, also known by the English term of “curtain walls”, and in particular of the type with punctually suspended panes. Facades of the type indicated above are formed by a plurality of mutually adjacent panes, arranged to form a substantially continuous surface of a building. In most cases, the panes are entirely made of glass, to form total see-through suspended facades.

2. Prior Art

Facades or glass walls of the type indicated above usually comprise a metal frame, positioned towards the interior of the building, whereto brackets are associated for supporting the panes; the latter, having for example a quadrangular shape, are provided with through holes, usually formed in correspondence with the respective corner or peripheral areas. Said holes are used to fasten particular connecting elements, substantially in the form of flathead bolts, connected in fixed fashion to the aforesaid brackets, which unload stresses on the aforesaid frame. The various panes supported by the frames are appropriately mutually sealed along the contiguous edges, for example by means of appropriate adhesive materials, such as special silicones.

Examples of embodiments of structural glass walls, with the related frames, brackets and connecting elements are described, for example, in EP-A-1 083 289 and EP-A-0 847 475.

In the facades or glass walls of the type indicated above the various panes, supported in the manner described above, are fastened in such a way as to maintain a stable position of lay. The only movements of the panes are those due to any minimal deformations of the support structure, caused for example by heat stresses, or by external stresses (wind, earthquakes, etcetera). For this reason, the sealing material is usually elastic, in order to allow, in addition to the necessary characteristics of air and water tightness, also a minimal possibility of relative movement between the panes, to offset the aforesaid deformations.

Drawbacks of the Prior Art

According to the current state of the art, the provision of openings, such as windows, presupposes the use of particular frames or dedicated section bars, which must be fastened within the curtain wall; in practice, therefore, in the point where a window is to be placed, one of the aforesaid frames is mounted instead of a pane, whereto the window is articulated or hinged.

In addition to complicating construction, this solution compromises the aesthetic homogeneity of the facade, because the aforesaid frames for the windows remain at least partially in view. Said drawback is further enhanced in the case of totally see-through suspended facades.

Purpose of the Invention

In light of the above, an object of the present invention is to provide a structural facade (or curtain wall), of the type set out above, provided with a window or door frame system of a new design and advantageous application, especially from the viewpoint of simplicity and mounting economy.

Another object of the invention is to indicate such a curtain wall in which the presence of windows is very “discreet”, in order to safeguard the stylistic homogeneity of the curtain wall itself.

These and other aims are attained, according to the present invention, by a curtain wall and by a window or door frame for curtain walls having the characteristics specified in the appended claims, which are to be considered as an integral part of the present description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention shall now be described with reference to the accompanying drawings, provided purely by way of non limiting example, in which:

FIG. 1 is a schematic front view of a portion of a structural glass wall according to the invention;

FIG. 2 is an enlarged portion of FIG. 1;

FIG. 3 is an enlarged and partially sectioned detail of FIG. 1;

FIG. 4 is a schematic section view according to the line IV-IV of FIG. 2;

FIG. 5 is a partial schematic section view according to line V-V of FIG. 4;

FIG. 6 is a partial schematic section view according to line VI-VI of FIG. 4;

FIG. 7 is a partial schematic section view according to line VII-VII of FIG. 2;

FIG. 8 is a first schematic lateral view of the structural glass wall of FIG. 1, in a first condition of use;

FIG. 9 is a second schematic lateral view of the structural glass wall of FIG. 1, in a second condition of use;

FIG. 10 is an enlarged detail of FIG. 8;

FIG. 11 is an enlarged detail of FIG. 9.

DETAILED DESCRIPTION OF SOME PREFERRED EMBODIMENTS OF THE INVENTION

In FIGS. 1 and 2, reference number 1 globally designates a portion of a continuous curtain wall according to the invention. In the exemplified case, the curtain wall 1 comprises a plurality of punctually suspended clear glass panes 2, so that in the remainder of the description the curtain wall shall also be indicated with the term “glass wall”.

As in the prior art, the glass wall 1 comprises a support frame, positioned towards the interior of the building, constituted by a series of cross members and uprights, some of which are designated as 3. As shown for example in FIG. 4, brackets or supports 4, also known in itself, are fastened in a known manner to said uprights 3; in the exemplified case, and as visible in FIGS. 4, 5 and 7, the brackets 4 comprise a central portion 4A, for anchoring to a respective upright 2, wherefrom four inclined arms 4B radially depart, at whose free end a sort of eyelet 4C is defined.

The panes 2, which are here rectangular-shaped, have, at each angle area, a respective through hole, for fastening respective connecting elements 5; in the exemplified case, and as visible for example in FIGS. 4, 5 and 7, the connecting elements 5 are substantially in the form of flathead bolts, constructed substantially according to the prior art (see the previously mentioned prior documents); on one hand, the connecting elements 5 are fastened in correspondence with the aforesaid through holes of the panes 2 and, on the other side, they are fastened each in a related eyelet 4C of a respective bracket 4, in known manners.

The contiguous edges of the various panes 2 are sealed to each other by suitable means, such a silicone material designated as 6 in FIGS. 1, 2 and 3, which guarantees the necessary tightness against air and water/humidity and which has a certain degree of elasticity.

Also in FIG. 1, the reference 2′ designates a glass pane that is substantially similar to the ones already designated as 2, but provided with only three through holes, and in particular two upper holes, each formed in correspondence with a respective angle area of the pane 2′, and a lower hole, formed in the intermediate area of the lower part of the pane 2′. As shall become readily apparent below, the upper holes are provided for fastening respective connective element 5′, which are connected in articulated fashion to the respective bracket 4, whilst the lower hole is provide for fastening a respective connecting element 5″ associated to an actuation element.

Along the edge of the pane 2′ operates, instead of the sealing material 6, a peripheral gasket 7 which, in a preferred but non exclusive embodiment, is capable of assuming two different operative conditions. Again in FIGS. 1-6, the number 10 globally designates an actuation and control unit for producing an angular actuation of the pane 2′, so the latter can serve as a window or the like, able to be opened and closed as needed.

As shown in FIGS. 3 and 4, the unit 10 comprises a case 11, provided with flanges 12 for its anchoring between two brackets 4, which occurs in manners and with means that are known in themselves. Inside the case 2 two batteries are mounted, designated as 13, a compressed air generator or compressor designated as 14, an actuator 15 and a control system 16, including a receiver 17 of radio-frequency or infrared signals, which is a part of a remote control system.

In the exemplified case, the batteries 13 are of a known rechargeable type, for example 12V, and provided to supply power to the compressor 14, the actuator 15 and the unit 16. The compressor 14, small sized and with an optional air tank, is also of a known design, for example of the type with reversible pump, similar to those which can be powered by means of a cigarette lighter power outlet on motor vehicles, for inflating and deflating rubber boats and the like. The actuator 15, in the exemplified case, is a linear electrical actuator of the chain type, i.e. the type in which an electric motor is able to determine the movement of a chain in two different directions, towards the exterior and the interior of the body of the actuator itself. The control system 16 is obtained in manners that are known to those skilled in the art, to perform the functions described below.

Outside the case 11, in its upper part, one or more photo-voltaic cells are mounted, designated as 18; said cells 18 are connected to the control unit 16, which complements a provision for recharging the battery 13, also known in itself. Preferably, the upper part of the body 11 is inclined (see for example FIG. 6), in such a way that the cells 18 are oriented towards the pane 2′, to be able to receive sunlight; the cells 18 can also be mounted directly on a pane 2′ or 2′.

In the exemplified embodiment, the gasket 7 co-operating with the glass pane 2′ is internally hollow and it is made of elastomeric material, or otherwise of elastic or flexible material, preferably transparent; the inner cavity of the gasket 7, designated as 7A in FIGS. 5-7, is connected, by means of at least one tube designated as 19 in FIG. 4, to the compressor 14; in this way, in a first operating mode, the compressor 14 is able to generate a flow of air which is injected into the cavity 7A, until achieving the “inflation” of the gasket 7, to maintain then said condition at the end of its activation; in a second operating mode, the compressor 14 allows instead the aspiration or otherwise the exit of the air contained inside the cavity 7A of the gasket 7.

As shown in FIGS. 5-7, the edges of the pane 2′ can be shaped to define a sort of throat, for example V-shaped, for housing a respective portion for fastening the gasket 7, in such a way that the diametrically opposite portion of the gasket is suitable to operate in sealed fashion on the edge of the contiguous pane 2, when the gasket 7 is in the respective inflated condition. Between the surfaces of the aforesaid throat and fastening portion of the gasket 7, a glue may be provided.

The edges of the panes 2 could also be provided with a similar throat or seat, able to receive a respective sealing portion of the gasket 7, when the latter is in the respective inflated condition.

FIG. 6 shows a schematic section of the unit 10, within which the actuator 15 is housed (note that, for the sake of greater clarity, in this figure the representation of a bracket 4 has been omitted); as can be noted, from the body of the actuator 15 an actuating element 15A partially projects, through a respective passage, which here is assumed to be a metal chain.

The free end of the chain 15A is operatively coupled, preferably by means of an articulation S1, to a connecting element 5″, substantially similar to the elements 5, which is fastened in correspondence with the aforesaid through hole present in the central area of the lower part of the pane 2′. In a possible embodiment, the element 5″ could be glued to the surface of the pane 2′ oriented towards the interior of the building, and hence without the need for the aforesaid lower through hole.

FIG. 5 shows one of the brackets 4 which are at the angle areas of the lower part of the pane 2′. As stated, the pane 2′ does not have through holes in the lower corner areas; in this case, instead of a connecting element 5, a simple support element 20 is fastened to the bracket, preferably having a head made of synthetic and elastic material 20A, whereon the surface of the pane 2′ which is oriented towards the interior of the facade 1 or of the building can be set down.

FIG. 7 instead shows one of the brackets 4 which are located at the corner areas of the upper part of the pane 2′. As it is readily apparent, in this case connecting elements 5′ are provided, fastened in the upper through holes of the pane 2′, which are substantially similar to the element 5 but are coupled in articulated fashion to the respective bracket 4, for example through an articulated joint or hinge, shown only schematically and designated as S2.

In FIGS. 8, 10 and 9, 11 the pane 2′ is shown in two possible operative conditions, respectively closed and open.

In the closed condition, as shown in FIGS. 8 and 10, the pane 2′ is substantially flush with the other panes 2 which compose the wall 1. In this condition the gasket 7 is full of air, i.e. inflated, in order to exert its sealing action between the edges of the pane 2′ and the edges of the panes 2 contiguous thereto. In this situation, the action of the gasket 7 also contributes to maintain the pane 2′ in the respective closed position, i.e., aligned relative to the panes 2. This position is also maintained by virtue of the presence of the chain 15A, which is connected by means of the respective connecting element 5″ to the pane 2′; note on this point that, in the condition with the actuator 15 not powered, the chain 15A is locked in position, holding the surface of the pane 2′ in contact with the heads 20A of the supports 20, as shown in FIG. 8, thereby preventing the pane from moving.

When the opening of the pane 2′ is desired to be controlled, i.e. the pane 2′ is to be brought to the position shown in FIGS. 9-10, the user operates a remote control, not shown, pressing an opening push-button. The signal emitted by the remote control is received by the respective receiver 17 integrated in the control system 16, which consequently determines at first the deflation of the gasket. Depending on the chosen implementation, the deflation can be active, in the sense that the compressor 14 will operate in suction, removing the air present in the chamber 7A inside the gasket 7. Alternatively, the compressor 14 can simply operate to place the chamber 7A in communication with the outside environment, in order to allow the easy deformation of the gasket 7 during the opening movement of the pane 2′.

After a predefined time, deemed sufficient to eliminate air pressure inside the gasket 7, the system 16 powers the actuator 15, in a first direction of operation. The electric motor inside the actuator 15 thus causes the chain 15A to project outside the case of the actuator itself, and hence determines a thrust on the connecting element 5″.

In this way, since it is not constrained inferiorly to the brackets 4, but only set down on the heads 20A of the elements 20, the pane 2′ is moved angularly towards the exterior of the curtain wall 1, by virtue of the presence of the articulated support to the upper brackets 4, constituted by the connecting elements 5′ and by the respective joints S2.

Upon reaching the desired degree of opening for the pane 2′, the pressure of a stop push-button present on the remote control determines the interruption of the supply of power to the actuator 15, with the consequent arrest of the motion of the pane, in the operative condition shown in FIGS. 9, 11. The actuator 15 will preferably comprise within it an end-of-stroke device, known in itself, such as a micro-switch, able to detect the reaching of the maximum possible degree of projection of the chain 15A outside the body of the actuator 15, in such a way as automatically to command it to stop.

When the pane 2′ is to be brought back to the position as per FIGS. 8, 10, the user need do no more than operating a closure push-button on the remote control. This causes the actuator 15 to operate in the opposite direction with respect to the previous one, i.e. rewinding the chain 15A inside the body of the actuator itself, which causes an angular motion of the pane 2′ that is opposite to the previous one. The pane 2′ then returns to bear down on the head 20A of the elements 20 which, as stated, are preferably made of elastic or resilient material.

In this case, too, the reaching of the closed position can advantageously be detected or determined by end-of-stroke means, known in themselves, for example in the form of micro-switches, positioned inside the actuator 15 or provided for directly detecting the reaching, by the internal face of the pane 2′, of a predefined closed position.

Once said closed position has been reached, the control system 16 controls the compressor 14, such that the latter admits compressed air to the cavity 7A of gasket 7; in this way, the gasket is thus inflated, in order to newly operate for sealing and locking the edges of the pane 2′ with respect to the edges of the panes 2 contiguous thereto.

In the embodiment of the invention exemplified in the figures, the photo-voltaic cells 18 are oriented, as stated, towards the wall 1, in order to receive the light that passes through it and thereby generate electrical energy to recharge the batteries 13 that power the unit 10. Naturally, nothing prohibits the unit 10 from being powered directly by an electrical wire connected to the electrical system of the building, in which case the batteries 13 could still be provided as an auxiliary energy source in case of accidental interruptions in mains voltage.

From the above description, the characteristics and the advantages of the present invention are readily apparent. Among its advantages, in particular, it is noted that the system described herein is easy to mount, by virtue of the use of a limited number of simple and economical components. The proposed solution allows to construct structural continuous facades and lass walls with no need to provide special section bars for mounting windows and other frames, which disrupt the overall appearance of the glass wall or facade.

Clearly, numerous variants to the system described as an example herein are possible for the person skilled in the art, without thereby departing from the scope of the inventive idea.

Instead of electrical components, the unit 10 could comprise different types of actuators. For example, the actuator 15 can be pneumatically operated, in which case a same compressed air generator can advantageously be used to achieve both the inflation of the gasket 7 and the physical actuation of the pane 2′. Equally, the actuator 15 could be hydraulic or oleodynamic, and the gasket 7 could also be operated hydraulically, i.e., assume the respective expanded condition when filled with a liquid, for instance an oil, with the passage to the open position achievable by evacuating said fluid from the interior of the cavity 7A.

Alternatively, or in combination with one of the above solutions, the unit 10 could comprise a manual actuation system, operative to generate the force for actuating the pane 2′ and/or the positive/negative pressure needed by the gasket 7 (when a gasket is used which require said pressure).

In the case exemplified above, the pane 2′ can perform angular movements around a horizontal axis, which extends substantially near the upper terminal area of the pane itself. However, it is clear that the axis of rotation could be near the lower end, or in an intermediate area of the pane. Obviously, the axis of rotation could also be positioned vertically, in which case the case 11 of the unit 10 shall also be positioned vertically, and also fastened between two brackets 4.

The shape of the case 11 may differs from the one shown herein, for example with a cross section that is square, rectangular, circular, etcetera.

The gasket 7 could be associated to the edges of the panes 2 that surround the pane 2′, instead of being mounted thereon. The system could also comprise a “passive” gasket, i.e., a traditional gasket, or two cooperating gaskets, for example in male-female form, one borne by the pane 2′ and the other one borne by the panes 2.

Section bars for fastening the gasket or gaskets could be associated to the edges of the panes 2 or 2′, preferably made of transparent material.

The gasket 7 could have a different section from the one shown by way of non limiting example, and—as mentioned—also have a different type of operation.

In this view, for example, the gasket and/or a support or fastening means thereof could be at least in part made of an active shape memory material, such as an SMP (Shape Memory Polymer). As is well known, said polymers are able to modify their rigidity and shape according to the temperature whereto they are exposed and rapidly pass, if heated, from a rigid state to a highly deformable rubbery state, then returning equally rapidly, when heating ceases, to their original shape and hardness. Thanks to their “memory”, SMPs can return to their original shape an infinite number of times, if taken beyond their critical temperature again.

In the proposed variant, therefore, the gasket or a support thereof could at least in part be made of a shape memory polymer, suitably connected to electrical power supply means, to be heated by Joule effect above its transition temperature, the aforesaid power supply means being driven by the control system 16 of the unit 10. In the condition with the pane 2′ closed, as shown in FIGS. 8, 10, the SMP gasket is not heated, in order to remain in the respective rigid state and it serves its sealing and locking function; if opening of the pane 2′ is desired, to the position shown in FIGS. 9, 11, the SMP gasket is heated by Joule effect, in order to pass to the respective rubber and deformable state, thereby allowing the movement of the pane, obtained in the manners described above; once the opening is accomplished, the power supply to the SMP gasket can then be interrupted. Preferably, the SMP gasket will also be powered while the pane 2′ is being closed, so that it can assume its respective rubbery and deformable state, and thus be able again to insinuate itself in contact with the edges of the panes 2 contiguous to the pane 2′; once the position visible in FIGS. 8, 10 is reached, electrical power supply will be interrupted, to allow the gasket to return to the respective rigid state and perform its sealing and locking function.

In the case of implementation with gasket 7 able to contain a fluid (air, gas, liquid, etcetera), the system for feeding the gasket could be provided with an operative sensor to monitor the pressure of the fluid inside the chamber 7A, in order to detect any pressure drops in the chamber and consequently activate the compressor 14 automatically, to assure a correct seal at all times. 

1. A structural facade (1) comprising a plurality of panes or the like (2, 2′), in particular made of transparent material, locally suspended in side by side positions substantially according to a same plane of lay, a fixed structure (3) whereto support means (4, 5, 5′, 5″) for the panes (2, 2′) are associated, the support means (4, 5, 5′, 5″) of each pane (2, 2′) comprising a plurality of connecting devices (5), where each connecting device (5, 5′, 5″) is sustained, at one side, by means of the fixed structure (3) and is fastened, at another side, in a localised area of the respective pane (2, 2′), and where each pane (2, 2′) has at least one edge that is contiguous to an edge of another pane (2, 2′), between the contiguous edges sealing means (6, 7) being provided, characterised in that at least a first of said panes (2′) is capable of moving (2′) relative to said plane of lay, said sealing means (6,7) comprise first sealing means (7) co-operating with said first pane (2′) and able to be operated to pass from a respective operative condition to a respective inoperative condition, and vice versa, first actuating means (14) are provided, able to be selectively operated to cause passage of the first sealing means (7) between the respective operative and inoperative conditions.
 2. The facade according to claim 1, characterised in that, in said operative condition, said first sealing means (7) are at least in part operative to hold said first pane (2′) in said plane of lay.
 3. The facade according to claim 1, characterised in that second actuating means (15) are provided, able to be selectively operated to cause displacement of said first pane (2′) relative to said plane of lay, said second actuator means (15) being preferably operative to hold said first pane (2′) in said plane of lay when said first sealing means (7) are in said operative condition.
 4. The facade according to claim 1, characterised in that one or more connecting devices (5, 5′, 5″) are fastened each in a through hole present in the respective pane (2, 2′), said connecting devices (5, 5′, 5″) being preferably in the form of flathead bolts.
 5. The facade according to claim 1, characterised in that the connecting devices (5, 5″) fastened to said first pane comprise at least one of a first connecting device (5′) connected in an articulated fashion to said fixed structure (3), a second connecting device (5″) associated to a movable element (15A) actuated by actuating means (15).
 6. The facade according to claim 1, characterised in that said fixed structure (3) supports bearing means (20) whereon said first pane (2′) is held directly or indirectly in contact when the pane itself is in said plane of lay.
 7. The facade according to claim 1, characterised in that said first sealing means comprise a gasket (7).
 8. The facade according to claim 7, characterised in that said gasket (7) is made of elastic material and comprises an inner cavity (7A), said cavity being capable of containing a pressurised fluid when the gasket is in said operative condition.
 9. The facade according to claim 7, characterised in that said gasket (7), or a support means thereof, is at least in part made with a shape memory active material, such as a shape memory polymer, and said first actuating means comprise means operative to cause the heating of said active material.
 10. The facade according to claim 8, characterised in that said first actuating means comprise a compressed air generator (14), in particular connected to said cavity (7A) by means of a conduit (19).
 11. The facade according to claim 3, characterised in that said first actuating means (14) and second actuating means (15) are controlled by a control system (16), wherein said first actuating means (14), said second actuating means (15) and said control system (16) are preferably housed in a same unit (10).
 12. The facade according to claim 1, characterised in that electrical battery means (13) are provided, capable of supplying power to at least said first actuating means (14), wherein said batteries are of the rechargeable type and one or more photo-voltaic cells (18) are operatively connected to a circuit for recharging said batteries (13).
 13. The facade according to claim 11, characterised in that said control system (16) comprises end-of-stroke means, operative to detect or cause the reaching of a determined position by said first pane (2′), said end-of-stroke means comprising in particular at least one of: first end-of-stroke means, operative to detect or determine the reaching of a maximum degree of displacement of said first pane (2′) with respect to said plane of lay, second end-of-stroke means, operative to detect or determine the reaching, by said first pane (2′), of a predefined closure position.
 14. The facade according to claim 7, characterised in that said gasket (7) is at least partly mounted on at least one of said first pane (2′) and a second pane (2) contiguous thereto.
 15. The facade according to claim 3, characterised in that said first actuator means and/or said second actuator means comprise actuators selected in the group consisting of electrical actuators, pneumatic actuators, hydraulic actuators, manual actuators.
 16. The facade according to claim 1, characterised in that said first pane (2′) is mounted movable to effect angular motions around at least one of a substantially horizontal axis or a substantially vertical axis.
 17. A window or door system for a structural facade (1) which comprises a plurality of panes or the like (2, 2′), in particular made of transparent material, locally suspended in side by side positions substantially according to a same plane of lay, a fixed structure (3) whereto support means (4, 5, 5′, 5″) for the panes (2, 2′) are associated, the support means (4, 5, 5′, 5″) of each pane (2, 2′) comprising a plurality of connecting devices (5), where each connecting device (5, 5′, 5″) is sustained, at one side, by means of the fixed structure (3) and is fastened, at the other side, in a localised area of the respective pane (2, 2′), and where each pane (2, 2′) has at least one edge that is contiguous to an edge of another pane (2, 2′), between the contiguous edges sealing means (6, 7) being provided, characterised in that the system comprises at least a first one of said panes (2′), which is capable of moving (2′) relative to said plane of lay and with which first sealing means (7) co-operate, able to be driven to pass from a respective operative condition to a respective inoperative condition, and vice versa, first actuating means (14), able to be selectively operated to determine passage of said first sealing means (7) between the respective operative and inoperative conditions.
 18. A window or door system for a structural facade (1) which comprises a plurality of panes or the like (2, 2′), in particular made of a transparent material, locally suspended in side by side positions substantially according to a same plane of lay, a fixed structure (3) whereto support means (4, 5, 5′, 5″) for the panes (2, 2′) are associated, the support means (4, 5, 5′, 5″) of each pane (2, 2′) comprising a plurality of connecting devices (5), where each connecting device (5, 5′, 5″) is sustained, at one side, by means of the fixed structure (3) and is fastened, at the other side, in a localised area of the respective pane (2, 2′), and where each pane (2, 2′) has at least one edge that is contiguous to an edge of another pane (2, 2′), between the contiguous edges sealing means (6, 7) being provided, the system being characterised in that the connecting devices (5′, 5″) fastened to a first (2′) of said panes (2, 2′) comprise at least one connecting device (5′) fastened in a through hole present in the first pane (2′) and connected in an articulated fashion to said fixed structure (3), and a second connecting device (5″), associated to a movable element (15A) able to be selectively operated to cause displacement of said first pane (2′) relative to said plane of lay.
 19. The system according to claim 18, characterized in that said sealing means (6, 7) comprise first sealing means (7) co-operating with said first pane (2′) and able to be operated to pass from a respective operative condition to a respective inoperative condition, and vice versa, and in that actuating means (14) are provided, able to be selectively operated to cause passage of the first sealing means (7) between the respective operative and inoperative conditions.
 20. The system according to claim 18, characterized in that actuating means (15) are provided, able to be selectively operated to cause displacement of said first pane (2′) relative to said plane of lay. 